[0001] The present invention relates to an electrical connector assembly, to be utilized
in electric/electronic devices such as cellular telephones and digital cameras. The
present invention also relates to a receptacle connector and a plug connector, to
be employed in the electrical connector assembly.
[0002] Electrical connector assemblies having locking mechanisms, for locking connectors
to each other, are common. For example, there is known an electrical connector assembly
as disclosed in U. S. Patent No. 5, 879, 194 (Figure 8, Figure 9) . This electrical
connector assembly comprises a socket .(receptacle connector) which has a metallic
shielding member at
its exterior, and a plug (plug connector) for engaging with the socket. Locking protrusions comprising hooks
are formed on the shield member of the socket. The hooks are configured to engage
apertures, which are formed in the plug, during engagement of the socket and the plug.
To release the engagement, the locking protrusions are pressed.
[0003] In the electrical connector assembly disclosed in U. S. Patent No. 5,879,194, the
engaged state of the socket and plug is maintained by the positive engagement between
the hooks and the apertures. However, if an excessive force is applied in the extraction
direction of the plug while in the engaged state, the locking protrusions (hooks)
and the apertures may be damaged.
[0004] The application of excessive force occurs accidentally during normal use of electric/electronic
devices. For example, it is likely for a headphone cord to get caught on something,
while listening to music with a Mini Disc player through headphones. Cords for other
devices may also get caught on things, such as when listening to music downloaded
to a cellular telephone through earphones, recharging a digital camera, and connecting
cords in general. As a result, external force is applied to the cord, which then leads
to an excessive extraction force being exerted on connectors. This leads to the possibility
of damaging the locking portions of the connectors, or of dropping and damaging the
device itself. For this reason, connectors of this type, so-called multimedia interface
connectors, are manufactured with predetermined design standards that assume that
excessive external force will be applied thereto.
[0005] Specifically, connectors are designed to have engagement holding forces within a
predetermined range (5N to 10N, for example). In the case that an external force,
that is, an extraction force, over a certain load is applied, the connectors are to
separate without damage thereto. It is desired that connectors are designed to withstand
10, 000 cycles of a continuous insertion/extraction test, so that the above function
is not lost during the product lifetime thereof.
[0006] The present invention has been developed in view of the above circumstances. It is
an object of the present invention to provide an electrical connector assembly, a
receptacle connector, and a plug connector that maintain a comparatively low engagement
holding force over an extremely large number of insertions and extractions, thereby
releasing the engagement (lock) between the connectors in the case that external force
is applied.
[0007] It is another object of the present invention to provide an electrical connector
assembly, a receptacle connector, and a plug connector in which marring of the connectors'
surfaces due to the insertion and extraction thereof is avoided.
[0008] The electrical connector assembly of the present invention comprises:
a first connector having a first insulative housing for holding at least one first
contact; and
a second connector having a second insulative housing for holding second contacts
that contact the first contact during engagement with the first connector; wherein:
the first and second connectors comprise locking portions for locking with each other
during engagement with a low engagement holding force; and
protrusions for frictionally contacting the second connector are provided on the first
connector.
[0009] A configuration may be adopted wherein the electrical connector assembly further
comprises:
a metallic shell for containing the second insulative housing, provided at the exterior
of the first insulative housing; and wherein:
the locking portions comprise spring pieces, which are formed on the metallic shell,
and metallic locking pieces, which are provided on the second insulative housing.
[0010] It is preferable that the metallic locking pieces are provided at the two sides of
the second insulative housing, and that the tips of the locking pieces are protected
by the front end of the second insulative housing.
[0011] A configuration may also be adopted wherein the protrusions protrude from the metallic
shell toward the surface of the second insulative housing, during engagement of the
first and second connectors.
[0012] It is preferable that the longitudinal axes of the protrusions are perpendicular
to the engagement/disengagement direction of the first and second connectors. In addition,
it is preferable that the protrusions are provided at the top and the bottom of the
metallic shell.
[0013] Further, a configuration may be adopted wherein steps, for the protrusions to engage
with during engagement of the first and second connectors, are formed on the surface
of the second connector at positions corresponding to the protrusions of the first
connector.
[0014] The receptacle connector of the present invention is a receptacle connector for engaging
a plug connector, comprising:
an insulative housing; and
at least one contact held within the insulative housing; wherein:
a metallic shell is provided toward the exterior of the insulative housing;
locking portions comprising spring pieces, for locking with locking portions of the
plug connector during engagement therewith, is formed on the metallic shell; and
protrusions for frictionally contacting the surface of an insulative housing of the
plug connector, which is inserted into the interior of the metallic shell, are provided
on the metallic shell.
[0015] The plug connector of the present invention is a plug connector for engaging a receptacle
connector, comprising:
an insulative housing; and
at least one contact held in the insulative housing; wherein:
locking portions comprising metallic locking pieces, for locking with locking portions
of the receptacle connector with a low engagement holding force during engagement
therewith, are provided at the exterior of the insulative housing; and
a configuration is adopted so that protrusions of the receptacle connector frictionally
contact the insulative housing, when the plug connector is inserted into the receptacle
connector.
[0016] A configuration may be adopted wherein:
steps are formed on the surface of the insulative housing of the plug connector, at
positions corresponding to the protrusions of the receptacle connector.
[0017] Both the first and the second connectors of the electrical connector assembly of
the present invention comprise locking portions, which are locked to each other with
a low engagement holding force during engagement of the connectors. In addition, protrusions
for frictionally contacting the second connector are provided on the first connector.
Therefore, the following advantageous effects are exhibited.
[0018] Even if the locking portions become worn, a comparatively low engagement holding
force can be maintained between the connectors over an extremely large number of insertions
and extractions, by the engagement holding force due to the friction with the protrusions.
[0019] A configuration may be adopted wherein a metallic shell for containing the second
insulative housing is provided at the exterior of the first insulative housing; and
wherein: the locking portions comprise spring pieces, which are formed on the metallic
shell, and metallic locking pieces, which are provided on the second insulative housing.
In this case, a conductive path can be formed via the locking portions, and an integrated
shield (electromagnetic shield) for the connector assembly can be formed.
[0020] In the case that the protrusions protrude from the metallic shell toward the surface
of the second insulative housing of the second connector, formation of the protrusions
is facilitated.
[0021] In the case that the longitudinal axes of the protrusions is perpendicular to the
engagement/disengagement direction of the first and second connectors, marring is
less likely to occur on the surface of the second connector during insertion and extraction
thereof.
[0022] A construction may be adopted wherein steps, for the protrusions to engage with during
engagement of the first and second connectors, are formed on the surface of the second
connector at positions corresponding to the protrusions of the first connector. In
this case, a "click" is generated by the engagement of the protrusions and the steps
when the connectors are completely engaged with each other. This "click", combined
with the "click" generated by the engagement of the locking portions, increases the
"click" perceived by a user. Therefore, complete engagement can be positively perceived
through the sense of touch of the user's hands (fingers). Further, the engagement
holding force can be increased by the engagement of the protrusions with the steps.
[0023] The receptacle connector of the present invention comprises an insulative housing;
a metallic shell provided toward the exterior of the insulative housing;
locking portions comprising spring pieces, for locking with locking portions of a
plug connector during engagement therewith, formed on the metallic shell; and
protrusions for frictionally contacting the surface of an insulative housing of the
plug connector, which is inserted intc the interior of the metallic shell, provided
on the metallic shell By this construction, the receptacle connector is capable of
maintaining a comparably low engagement holding force with the plug connector over
an extremely large number of insertions and extractions.
[0024] The plug connector of the present invention comprises:
locking portions comprising metallic locking pieces, for locking with locking portions
of the receptacle connector with a low engagement holding force during engagement
therewith, are provided at the exterior of the insulative housing; and
a configuration is adopted so that protrusions of the receptacle connector frictionally
contact the insulative housing, when the plug connector is inserted into the receptacle
connector.
By this construction, the plug connector is capable of maintaining a comparably low
engagement holding force with the receptacle connector over an extremely large number
of insertions and extractions. In addition, this construction enables a conductive
path to be formed with the receptacle connector, via the locking portions.
[0025] Figure 1 is a perspective view of a receptacle connector, which is the first connector
of an electrical connector assembly according to the present invention, from its front
end.
[0026] Figure 2 is a perspective view of the receptacle connector of Fiqure 1, from its
rear end.
[0027] Figure 3 is a front view of the receptacle connector of Figure 1.
[0028] Figure 4 is a side view of the receptacle connector of Figure 1.
[0029] Figure 5 is a plan view of the receptacle connector of Figure 1.
[0030] Figure 6 is a bottom view of the receptacle connector of Figure 1.
[0031] Figure 7 is a perspective view of a plug connector according to the present invention,
from its rear end.
[0032] Figure 8 is a front view of the plug connector of Figure 7.
[0033] Figure 9 is a side view of the plug connector of Figure 7.
[0034] Figure 10 is a sectional view of the plug connector, taken along line X-X in Figure
8.
[0035] Figure 11 is a partial sectional view of the assembly in a state in which the plug
connector and the receptacle connector are completely engaged.
[0036] Figure 12 is a perspective view of a modified receptacle connector.
[0037] Figure 13 is a perspective view of a plug connector, which is a constituent of an
electrical connector assembly according to a second embodiment of the present invention.
[0038] Figure 14A and Figure 14B show a receptacle connector, which is to be engaged with
the plug connector of Figure 13, wherein Figure 14A is a perspective view and Figure
14B is a bottom view.
[0039] Figure 15 is a vertical sectional view of the electrical connector assembly according
to the second embodiment, in a state in which the receptacle connector and the plug
connector are completely engaged.
[0040] Hereinafter, preferred embodiments of an electrical connector assembly C (hereinafter,
simply referred to as "assembly"), the receptacle connector, and the plug connector
will be described with reference to the attached drawings. Figure 1 is a perspective
view of a receptacle connector 1, which is the first connector of the assembly C,
from its front end 2. Figure 2 is a perspective view of the receptacle connector 1
from its rear end 4. Figure 3 is a front view, Figure 4 is a side view, Figure 5 is
a plan view, and Figure 6 is a bottom view of the receptacle connector 1. Hereinafter,
a description will be given with reference to Figure 1 through Figure 6.
[0041] The receptacle connector 1 comprises: an insulative housing 6 (hereinafter, simply
referred to as "housing"); contacts 8 (first contacts) , which are held by the housing
6; and a shielding member, that is, a shell 10, which is provided so as to cover the
periphery of the housing 6.
[0042] As most clearly illustrated in Figure 3, the housing 6 comprises a main body having
a substantially rectangular shape when viewed from the front. Tapers 12 are formed
at both lower corners of the main body 14. A contact supporting plate 16 protrudes
from the front end of the main body 14. A plurality of contact receiving grooves 18
are provided at predetermined intervals in the upper and lower surfaces of the contact
supporting plate 16. The contacts 8 are press fit into the contact receiving grooves
18 and placed therein. Each of the contacts 8 comprises: a tine 22 that extends toward
the rear of the main body 14 to be connected to a circuit board 26 (refer to Figure
4); and a contacting portion 24 for contacting second contacts 104 (refer to Figure
7), which will be described later.
[0043] Next, the shell 10 will be described. The shell 10 is formed by punching and bending
a single conductive metal plate so as to be of a shape that surrounds the periphery
of the main body 14. The ends of the shell 10 abut each other at a seam 60, to house
the entirety of the housing 6 therein. The seam 60 is formed as a dovetail joint,
which causes it to be difficult for the ends of the shell 10 to become separated.
Tongue pieces 30 are formed at both sides of an upper wall 28 of the shell 10, toward
the rear end 4 thereof. The tongue pieces 30 are formed by punching, and are of a
cantilevered structure having their fixed ends at the upper wall 28. The tongue pieces
30 are formed perpendicular to an insertion/extraction direction 62 (refer to Figure
1) , and are bent inwardly. Recesses 32 are formed in the main body 14 at positions
corresponding to the tongue pieces, and the tongue pieces 30 engage the interiors
of the recesses 32. Tongue pieces 34, which are similar to the tongue pieces 30, are
formed at a bottom wall 36 of the shell 10, and engage recesses 38, which are formed
in the lower portion of the main body 14. The shell 10 is fixed to the housing by
the engagement of the tongue pieces 30 and 34 with the recesses 32 and 38.
[0044] Downwardly extending mounting legs 42 and 44 are formed by cutting and bending the
shell 10 at the front and rear of both side walls 40 thereof. The mounting legs 42
and 44 are for mounting to the circuit board 26. L-shaped spring pieces 46 are formed
by punching out the upper wall 28 and the side walls 40 in the vicinity of the front
end 2 of the shell 10. The spring pieces 46 have their fixed ends at the upper wall
28, and are formed symmetrically on the right and left side walls 40 of the shell
10. Each of the spring pieces 46 comprises: an arm 48 that extends from the upper
wall 28 through the side wall 40; and an engaging piece 50 that extends rearward from
the tip of the arm 48, perpendicular thereto. An engaging protrusion 52 (locking portion)
that protrudes inwardly in an arcuate manner is formed on each engaging piece 50.
The rear portions of the engaging protrusions 52 function as engaging surfaces 52a
(refer to Figure 11) . Here, it is important to note that the engaging protrusions
52 are arcuate in shape, and that they do not have engaging surfaces which are perpendicular
to the insertion/extraction direction 62. For this reason, an engagement holding force
becomes comparatively low, when the receptacle connector 1 is engaged with a plug
connector 100 (refer to Figure 7), which will be described later.
[0045] Next, press contacting protrusions 54 and 56 (beads), which are characteristic features
of the present invention, will be described. The press contacting protrusions 54 and
56 are formed on the upper wall 28 and the lower wall 36 of the shell 10, by inwardly
punching the upper wall 28 and the lower wall 36. The press contacting protrusions
54 and 56 protrude slightly from the upper wall 28 and the lower wall 36 toward the
interior of the shell 10, respectively. The dimensions of the press contacting protrusions
54 and 56 are such that they slidingly contact an insulative housing 102 of the plug
connector 100 (refer to Figure 7) when the plug connector 100 and the receptacle connector
1 are engaged with each other. The two press contacting protrusions 56 on the bottom
wall 36 are substantially ellipsoid in shape, and are provided on both sides of the
seam 60. The press contacting protrusions 54 and 56 have longitudinal axes 58 and
59, respectively. The longitudinal axes 58 and 59 are perpendicular to the insertion/extraction
direction 62 of the connectors. The press contacting protrusions 54, 56, and 56 are
formed at positions that face each other, to balance the force which is exerted on
the insulative housing 102 in the vertical direction.
[0046] The longitudinal axes 58 and 59 are perpendicular to the insertion/extraction direction
62. In the case that the longitudinal axes 58 and 59 are parallel to the insertion/extraction
direction 62, the upper surface 112a and the lower surface 112b of the insulative
housing 102 are likely to be marred. Particularly in the case that contact portions
54a and 56a (refer to Figure 3) of the press contacting protrusions 54 and 56 are
linear and parallel to the insertion/extraction direction 62, the upper surface 112a
and the lower surface 112b of the insulative housing 102 become scored, causing linear
marks to be formed thereon. This decreases the engagement holding force, and also
deteriorates the outward appearance of the plug connector 100. Further, shavings from
the scoring may become attached to the contacts 8 and contacts 104 (refer to Figure
7), thereby adversely affecting the contact properties therebetween.
[0047] Next, the plug connector 100, which is the second connector, will be described with
reference to Figure 7 through Figure 10. Figure 7 is a perspective view of the plug
connector 100 from its rear end. Figure 8 is a front view, Figure 9 is a side view,
and Figure 10 is a sectional view taken along line X-X in Figure 8, of the plug connector.
Figure 11 is a partial sectional view of the assembly C in a state in which the plug
connector 100 and the receptacle connector 1 are completely engaged. The plug connector
100 comprises: a plastic insulative housing 102 (hereinafter, simply referred to as
"housing"); contacts 104 (second contacts), which are held by the housing 102; and
locking pieces 106, which are mounted on both sides of the housing 102. The housing
102 comprises a main body 108, which is shaped as a rectangular block, and an engaging
portion 112, which protrudes toward the front via a step 110. Contact apertures 114
are formed in the housing 102, at positions corresponding to those of apertures 20
of the receptacle connector 1. The contact apertures 114 are provided as two rows,
which are separated in the vertical direction. The contact apertures 114 penetrate
through the housing 102 of the plug connector 100 in a direction parallel to the insertion/extraction
direction 62. The contacts 104 are press fit within the contact apertures 114 from
the rear ends thereof. As illustrated in Figure 11, each of the contacts 104 comprises:
a tine 116 for connecting to a wire (not shown) or a circuit board; a press fit portion
120, which has barbs 118 at both lateral edges thereof; and a contact portion 122
for contacting the contact 8. When the contacts 104 are press fitted into the hosing
102, the barbs 118 frictionally engage with the housing 102, thereby fixing the contacts
104 to the housing 102.
[0048] Apertures 124, for the locking pieces 106 to penetrate, are formed at both sides
of the rows of contacts in the main body 108 of the housing 102. Locking piece receiving
grooves 126 that communicate with the apertures 124 are formed at both sides of the
engaging portion 112, parallel to the insertion/extraction direction 62. The locking
piece receiving grooves 126 extend to the vicinity of an engagement surface 128. In
other words, the tips 106a of the locking pieces 106, which are held within the locking
piece receiving grooves 126, are not exposed at the engagement surface 128. The locking
piece receiving grooves 126 are of widths that are capable of receiving the lateral
edges 106b of the locking pieces 106 therein. As described above, the locking pieces
106 are held by the housing 102 so that neither the tips 106a nor the lateral edges
106b thereof are exposed to the exterior. Therefore, fingers and the like are prevented
from contacting the edges of the locking pieces, thereby securing safety. That is,
electrical connection requirements can be satisfied while maintaining safety.
[0049] Each of the locking pieces 106 comprises: a pressing portion 132 at its rear end,
that abuts the rear surface 130 of the housing 102; and barbs 134 (refer to Figure
10) for engaging the housing 102, formed at the lateral edges of the locking piece
106 in the vicinity of its rear end. Cutouts 138 are formed in both lateral edges
106b at the tip of each of the locking pieces 106. Outwardly protruding engaging protrusions
140 (locking portions) are formed at the cutouts 138. Each engaging protrusion 140
comprises: a forward facing inclined surface 140a; and a rearward facing inclined
surface 140b. When the plug connector 100 and the receptacle connector 1 are engaged,
the engaging protrusions 140 and the engaging protrusions 52 engage each other. This
engagement state will be described with reference to Figure 11.
[0050] As clearly illustrated in Figure 11, the contacts 8 and the contacts 104 contact
each other, and are frictionally engaged. In addition, the spring pieces 46 and the
locking pieces 106 are engaged to each other by the engagement between the engaging
protrusions 52 and the engagement protrusions 140, that is, their locking portions.
Immediately prior to complete engagement, the spring pieces 46 flex toward the exterior
(downward in Figure 11) due to its elasticity. When the engaging protrusions 52 ride
over the engaging protrusions 140, the spring pieces 46 elastically return to engage
with the locking pieces 106. Due to this flexure and return, a "click" is generated
when complete engagement is achieved. In this engaged state, the inclined surfaces
140b of the lock pieces 106 are engaged with the inclined engaging surfaces 52a of
the spring pieces 46. The spring pieces 46 and the locking pieces 106 are both metallic.
Therefore, they are capable of forming a conductive electrical path. In the present
invention, the shell 10 is grounded to the circuit board 26, thereby forming an integrated
shield (electromagnetic shield).
[0051] In addition, the press contacting protrusions 54 and 56 of the receptacle connector
1 slidingly contact the flat upper surface 112a and the flat lower surface 112b of
the engaging portion 112 of the plug connector 100 when the connectors are engaged.
This contact state is maintained after complete engagement. The frictional force of
this contact state also operates as engagement holding force between the connectors.
[0052] If excessive force is exerted on the plug connector 100 in the extraction direction
indicated by arrow 142 while in the engaged state, a force is applied on the inclined
surfaces 140b that attempts to move them in the direction of arrow 142. This force
works to cause the inclined surfaces 140b to flex the engaging surfaces 52a outward.
When this force exceeds the engagement holding force of the engaging protrusions 52
and the engaging protrusions 140, the spring pieces 46 are flexed outward to release
the engagement, and the plug connector 100 is extracted.
[0053] At this time, the engaging protrusions 54 and 56 generate resistance against the
excessive force in the extraction direction, by frictionally contacting the housing
102 of the plug connector 100. However, the connectors are designed so that the resistance
is not sufficient to prevent extraction. The spring pieces 46 and the locking pieces
106 become worn due to metallic abrasion, after a great number of insertions and extractions.
However, the press contacting protrusions 54, 56, and 56 simply contact the plug connector
100 in a sliding manner. Therefore, there is little possibility that the press contacting
protrusions 54, 56, and 56 will become worn. Accordingly, even if the spring pieces
46 and the locking pieces 106 become worn, an engagement holding force of a predetermined
amount or greater can be maintained. Further, the possibility that the surface of
the hosing 102 of the plug connector 100 will be marred is small, because the press
contacting protrusions 54 and 56 have longitudinal axes 58 and 59, which are perpendicular
to the insertion/extraction direction 62. In other words, the orientation of the press
contacting protrusions 54 and 56 prevent linear marks from being scored into the upper
surface 112a and the lower surface 112b of the housing 102. In addition, the frictional
engagement between the contacts 8 and 104 also serves to resist extraction. However,
in the case that the number of contacts 8 and 104 is small, the frictional force of
the press contacting protrusions 54, 56, and 56 are effective in maintaining a predetermined
engagement holding force.
[0054] As described above, the receptacle connector 1 and the plug connector 100 are designed
to have an engagement holding force great enough to damage either when excessive external
force is applied to the plug connector. Therefore, damage to the locking portions
of the plug connector 100 and the receptacle connector 1 is prevented. Consider a
case in which a connected device is a lightweight electronic device such as a cellular
telephone. If. external force pulls on the connectors and the engagement holding force
is too great, the electronic device itself may be pulled off of a table, fall, and
be damaged. However, this problem will not occur with the low engagement holding force
of the connectors according to the present invention.
[0055] A preferred embodiment of the present invention has been described above. However,
the present invention is not limited to the above embodiment. It goes without saying
that various changes and modifications are capable for those skilled in the art.
[0056] For example, Figure 12 is a perspective view of a modified receptacle connector 80.
As illustrated in Figure 12, the shape of the mounting legs 42 for mounting the receptacle
connector 1 to the circuit board 26 may be modified. The receptacle connector 80 differs
from the receptacle connector 1 in that the rearward mounting legs 82 of a shell 84
are of the SMT (Surface Mounting Technology) type, as opposed to the dip type. This
is because prying forces, which are likely to be exerted on the front portion during
insertion and extraction of the connectors, are less likely to be exerted on the rear
portion.
[0057] It is preferable for the press contacting protrusion 54 to have the contact portion
54a thereof be linear, in a direction perpendicular to the insertion/extraction direction
62. However, the contact portion 54a may have a desired length in the direction along
the insertion/extraction direction 62, in order to obtain an appropriate engagement
holding force.
[0058] The engaging protrusions 52 of the spring pieces 46 are arcuate. However, the shape
of the engaging protrusions may alternatively be inclines surfaces having comparatively
low engagement holding forces.
[0059] Next, an assembly C' , which has a greater number of contacts than the aforementioned
assembly C, will be described with reference to Figure 13 through Figure 15. Figure
13 is a perspective view of a plug connector 300 (second connector) , which is a constituent
of the assembly C' (refer to Figure 15) . Figure 14A is a perspective view of a receptacle
connector 200 (first connector), which is to be engaged with the plug connector 300.
Figure 14B is a bottom view of the receptacle connector 200. Figure 15 is a vertical
sectional view of the assembly C', in a state in which the receptacle connector 200
and the plug connector 300 are completely engaged.
[0060] As illustrated in Figure 13, the plug connector 300 differs from the plug connector
100 in that it has fourteen contacts 304 (second contacts) . The plug connector 300
also comprises steps 350a and 350b, for engaging press contacting protrusions 254
and 256 to be described later, of the receptacle connector 200. The steps 350a and
350b are formed on the upper surface 312a and the lower surface 312b, respectively,
of a housing 302 of the plug connector 300. Note that the steps 350a and 350b will
collectively be referred to as steps 350. The step 350a is formed on the upper surface
312a at a position corresponding to that of the press contacting protrusion 254 of
the receptacle connector 200. The step 350a is formed as a rearward extending flat
surface 351a, which has a width capable of receiving the width of the press contacting
protrusion 254. The steps 350b are formed on the lower surface 312b at positions corresponding
to those of the press contacting protrusions 256 of the receptacle connector 200.
The steps 350b are formed as rearward extending flat surfaces 351b, which have widths
capable of receiving the widths of the press contacting protrusions 256 (refer to
Figure 15). The depth of the step 350a is exaggerated in Figure 13 for the sake of
clear illustration thereof. However, the actual depths of the steps 350 are approximately
0.1mm.
[0061] The plug connector 300 comprises engaging protrusions 340 (locking portions), which
are formed on locking pieces 306. However, they are of the same construction as those
of the plug connector 100, so a detailed description thereof will be omitted.
[0062] Meanwhile, the receptacle connector 200 to be engaged with the plug connector 300
is of the same basic construction as the receptacle connector 1 of Figure 1, except
that fourteen contacts are provided therein, as illustrated in Figure 14. That is,
a press contacting protrusion 254, which is similar to the press contacting protrusion
54, is formed on an upper wall 228. In addition, two press contacting protrusions
256, which are similar to the press contacting protrusions 56, are formed on a bottom
wall 236. The press contacting protrusions 256 are formed at positions corresponding
to those of the steps 350b. The receptacle connector 200 comprises: a housing 206;
contacts 208 (first contacts); a shell 210; spring pieces 246; and engaging protrusions
252 (locking portions). However, as these parts are of the same construction as those
of the receptacle connector 1, detailed descriptions thereof will be omitted.
[0063] When the plug connector 300 and the receptacle connector 200 are engaged, the press
contacting protrusions 254, 256, and 256 engage with the steps 350, as illustrated
in Figure 15. The engagement holding force between the connectors is increased by
this engagement. In addition, the "click" of this engagement is combined with the
"click" of the locking portions 252 and 340. Thereby, complete engagement can be positively
perceived.
1. An electrical connector assembly (c) comprising:
a first connector (1) having a first insulative housing (6) for holding at least one
first contact (8); and
a second connector (100) having a second insulative housing (102) for holding second
contacts (104) that contact the first contact (8) during engagement with the first
connector (1); wherein:
the first and second connectors (1,100) comprise locking portions (52,140) for locking
with each other during engagement with a low engagement holding force; and
protrusions (54,56) provided on the first connector (1) for frictionally contacting
the second connector (100).
2. An electrical connector assembly (c) as defined in claim 1, further comprising:
a metallic shell (10) for containing the second insulative housing (102), provided
at the exterior of the first insulative housing (6); and wherein:
the locking portions comprise spring pieces (52), which are formed on the metallic
locking pieces (106), which are provided on the second insulative housing (102).
3. An electrical connector assembly (c) as defined in claim 2, wherein:
the protrusions (54,56) protrude from the metallic shell (10) towards a surface (112a,112b)
of the second insulative housing (102), during engagement of the first and second
connectors (1,100).
4. An electrical connector assembly (c) as defined in claim 1 or claim 3, wherein:
longitudinal axes (58,59) of the protrusions (54,56) are perpendicular to an engagement/disengagement
direction (62) of the first and second connectors (1,100).
5. An electrical connector assembly (c') as defined in any one of claims 1 through 4,
wherein:
steps (350a,350b), for the protrusions (254,256) to engage with during engagement
of the first and second connectors (200,300), are formed on a surface of the second
connector (300) at positions corresponding to the protrusions (254,256) of the first
connector (200).
6. A receptacle connector (1) for engaging a plug connector (100), comprising:
an insulative housing (6); and
at least one contact (8) held within the insulative housing (6); wherein:
a metallic shell (10) is provided toward an exterior of the insulative housing (6);
locking portions (52) comprising spring pieces are formed on the metallic shell (10),
for locking with locking portions (140) of the plug connector (100) during engagement
therewith; and
protrusions (54,56) are provided on the metallic shell (10) for frictionally contacting
a surface (112a,112b) of an insulative housing (102) of the plug connector (100),
which is inserted into an interior of the metallic shell (10).
7. A plug connector (100) for engaging a receptacle connector (1), comprising:
an insulative housing (102); and
at least one contact (104) held in the insulative housing (102); wherein:
locking portions comprising metallic locking pieces (106) are provided at an exterior
of the insulative housing (102) for locking with locking portions (52) of the receptacle
connector (1) with a low engagement holding force during engagement therewith; and
a configuration is adopted so that protrusions (54,56) of the receptacle connector
(1) frictionally contact the insulative housing (102) when the plug connector (100)
is inserted into the receptacle connector (1).
8. A plug connector (300) as defined in claim 7, wherein:
steps (350a,350b) are formed on a surface of the insulative housing (302), at positions
corresponding to the protrusions (254,256) of the receptacle connector (200).